US2935276A - Aircraft control system - Google Patents
Aircraft control system Download PDFInfo
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- US2935276A US2935276A US510931A US51093155A US2935276A US 2935276 A US2935276 A US 2935276A US 510931 A US510931 A US 510931A US 51093155 A US51093155 A US 51093155A US 2935276 A US2935276 A US 2935276A
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- pressure
- diaphragm
- control
- stick
- housing member
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B64—AIRCRAFT; AVIATION; COSMONAUTICS
- B64C—AEROPLANES; HELICOPTERS
- B64C13/00—Control systems or transmitting systems for actuating flying-control surfaces, lift-increasing flaps, air brakes, or spoilers
- B64C13/24—Transmitting means
- B64C13/38—Transmitting means with power amplification
- B64C13/40—Transmitting means with power amplification using fluid pressure
- B64C13/46—Transmitting means with power amplification using fluid pressure with artificial feel
Definitions
- the invention provides, in or for an aircraft, a flying control system embodying a variable gearing between the pilots stick and a control surface to be operated thereby and means for automatically changing the gearing in response to increase in air speed so that the travel of the stick required to produce unit displacement of the control surface in creases as the air speed increases.
- the stick may be connected to the input member of a servo mechanism for actuating the control surface by means of a linkage embodying an adjustable fulcrum, a device responsive to changes in air speed being provided for automatically adjusting said fulcrum so that the travel of the stick required to produce unit displacement of the control surface increases as the air speed increases.
- the device responsive to changes in air speed may be arranged to adjust said fulcrum through the agency of a hydraulic jack as described in United States patent applications Nos. 407,536 filed February 1, 1954, now U.S. Patent No. 2,783,006, granted February 26, 1927, and 458,334 filed September 27, 1954, now US. Patent No. 2,788,185, granted April 9, "1957. ternatively, as later described, an electric actuator may be used for the purpose.
- the device responsive to changes in air speed may be employed solely to change the gear ratio between the stick and the control surface and introduce no variable stiffness in the stick, which is provided with a conventional spring centering device.
- the gear change provided may be such that the stick force per unit of acceleration imparted to the aircraft in a manoeuvre is constant. The pilot will then require to displace his stick to the same extent, to obtain a given acceleration of the aircraft, over the entire speed range.
- the device responsive to changes in air speed may be arranged not only to change the gear ratio but may also act as a feel simulator to impose a resistance to movement of the stick whi h in creases with air speed.
- Fig. 1 is a diagrammatic view of a complete flying control system utilising a hydraulic jack to produce a gear change only
- Fig. 2 is a detail view showing a modification of the system of Fig. 1,
- Fig. 3 is a diagrammatic view of part of a system, similar to that of Fig. 1 but with the hydraulic jack arranged to act also as a feel simulator, and
- Fig. 4 is a vertical section through an alternative form of air speed responsive device for use in conjunction with the systems shown in Figs. 1 and 3.
- the stick 20 which is provided with centering springs 21, is connected by a mechanical linkage to a link 25 connected to the input member of a hydraulic jack 22 for actuating a control surface 23.
- the jack 22 is of conventional type and includes a control valve movable in opposite directions from a neutral position by a rod 24 to establish alternative pressure and exhaust connections to opposite ends f the jack cylinder and thereby to cause corresponding movement, in one direction or the other, of the jack piston, the rod 26 of which is connected to the control surface and also, by means of the usual follow-up link 27, to the rod 24 and to the link 25.
- the mechanical linkage comprises a link 28, carrying a pin 29 engaging a slot 36 in a lever 60, pivoted at one end at a fixed point 31 and pivoted at the other end 32 to the link 25.
- the gear change is effected by changing the position of the pin 29 in the slot 30, as will now be described.
- the position of the pin 29 in the slot 36 is controlled by a hydraulic jack 33, the piston 34 of which is anchored at a fixed point 35 and the cylinder 36 of which is connected to the aircraft structure by a stifi spring 37 and is also pivoted to a lever 38.
- the lever 38 is mounted on a fixed pivot 39 and is connected by a link 40 to the link 28.
- the hydraulic pressure in the cylinder 36 is caused to increase as the airspeed increases by an air speed responsive unit 41 of the kind described in United States appli-, cation No. 407,536/54.
- This includes a diaphragm 42, subject from a Pitot head 43, through pipes 44, 45, to total or ram pressure P, at its upper surface and to static pressure P at its undersurface.
- the unit 41 includes a control valve 46 which serves to determine the hydraulic pressure in a signal line 47 communicating with the cylinder 36.
- a push rod 48, carrying a valve 49 at its lower end, is interposed between the diaphragm 42 and the control valve 46, which is subject at its undersurface to the signal pressure, which is applied thereto through a duct 54).
- the control valve 46 occupies the neutral position shown, the signal pressure on its undersurface assisted by the pressure of a spring 51, balancing the pressure differential across the diaphragm 42. If the air speed increases, the control valve 46 will be depressed, so connecting the signal line 47 to a pressure inlet 52. The signal pressure accordingly increases to a value at which it is sufiicient to return the control valve to its neutral position. On decrease in the air speed, the control valve 46 rises, connecting the signal line 47 to an exhaust outlet 53, thus allowing the signal pressure to fall to a value at which the diaphragm 42 is able to return the control valve 45 to its neutral position.
- the signal pressure is applied through a duct 54 to the undersurface of the valve 49, which opens, as described in United States application No. 407,536/54, to permit of reduction of the signal pressure it, as the result of seizure of the control valve 46, the signal pressure should become excessive.
- the pressure in the cylinder 36 thus increases with increase in air speed and so gradually lifts the cylinder against the action of the spring 37, rocking the lever 38 clockwise and causing the pin 29 to move down in the 5101130.
- The, travelof the. stickrequiredto. produce. unitv displacement of the controLsurface thus increases as the air speed increases.
- the unit 41 senses the reduction in speed and re Jerusalem the hydraulic pressure in the cylinder 36.
- the system shown in Fig. 3 differs from that of Fig. 1 in that the stick is pivoted to the rod 550i the piston 34, the centering springs being omitted.
- the hydraulic jack 33 thus serves not only to provide the gear change, by shifting the pin 29 in the slot 30, but also as a feel simulator, providing, as in the case of United States application No. 407,536, a resistance to movement of the stick which increases with increase in air speed.
- the adjustable fulcrum in the linkage between the stick and the input 7 member of the jack for actuating the control surface will continue to be adjusted progressively as the air speed increases. It will be understood, however, that the relationship between air pressure and the'signal pressure communicated to cylinder 36 of the jack 33 in Figs. 1 and 3 may be made non-linear by utilizing any of the expedients described in United States applications Nos.
- a diaphragm 71 is also exposed to the pressure difierenease-ar f diaphragm 71 is smaller than the diaphragm 42, the signal pressure will continue to. increase with air speed but at a slower rate. If the diaphragm 71 is. largerthan-the diaphragm 42, the signal pressure will decrease as the air speed increases beyondthe. given value.
- the diaphragm 68 carries, at the side thereof exposed to total pressure'through the connection 67, an evacuated.
- the capsule 75 It bears against'a'roeker'ld, pivotedat 77 and bearing in turn against a lever 78 pivoted on a central pivot 79 and held' in contact with the rocker 76 by a spring 80. Normally, the free end 81 of the lever 78 is clear of the diaphragm 42. At a predetermined Mach number, however, the diaphragm 68 will have rocked'the 7 lever 78 sufficiently to render its end 81 eifective to exert a force on the diaphragm 42. Thereafter, the diaphragm- 63 will be effective toop-pose the diaphragm 42 and so reduce the signal pressure as the Mach number increases. If the capsule 75 is omitted, the diaphragm 68 will render the lever 78 eflfective on the diaphragm 42 at a given speed instead of a. a given Mach number.
- a power operated flying control system for aircraft comprising a control surface, a. pilots control member, a servo mechanism having an input member and an output member, said output member being connected to and serving to actuate the control surface, a linkage connecting the controlmember to the input memher, said linkage including a member which is adjustable to reduce, in response to increase in airspeed, the movement imparted by the linkage to the input member per unit of movement of the control member, a hydraulic jack including a piston member and a housing member, said housing member being movable in response to variations in hydraulic pressure in the housing and being connected to said adjustable linkage member and said piston member being connected to said control member and movable therewith against the resistance offered by the hydraulic pressure in the housing member, a spring opposing movement of said housing member, means re sponsive to changes in airspeed and means controlled byv said responsive device to establish in said housing member a variable hydraulic pressure which increases progressively asthe airspeed increases up to a given value at least of airspeed, said housing member moving
- diaphragm -71 carriesa stud;.73 moving with clearance in a claw 74fixed" to the diaphragm 42.
- a power operated flying control system forair craft comprising a control surface, a pilots control member, a servo mechanism having an input member and an output member, said output member being connected to andserving to actuate the control surface, a linkage connecting the control member to the input member, said linkage including a member which is adjustable to reduce, in response to increase'in airspeed, the movementvimparted by the linkage to the input member per unit of movement of the control member, azhydraulic jack including a piston member and a housing member, one of said members being movable in response to variations in hydraulic.
- a power operated flying control system for aircraft comprising a control surface, a pilots control member, a servo mechanism having an input member and an output member, said output member being connected to and serving to actuate the control surface, a linkage connecting the control member to the input member, said linkage including a member which is adjustable to reduce, in response to increase in airspeed, the movement imparted by the linkage to the input member per unit of movement of the control member, a hydraulic jack including a piston member and a housing member, one of said members being movable in response to variations in hydraulic pressure in the housing member and being connected to said adjustable member, a spring opposing movement of said movable member, a control valve subject to the hydraulic pressure in the housing member and normally closing an outlet from said housing member, said control valve being movable in opposite directions from a normal position to supply liquid under pressure to said housing member and to allow liquid to flow to exhaust from said housing member, a pressure-sensitive device exposed to the difierence between total pressure and static pressure and arranged to exert on the control valve
- a power operated flying control system for aircraft comprising a control surface, a pilots control member, a servo mechanism having an input member and an output member, said output member being connected to and serving to actuate the control surface, a linkage connecting the control member to the input memher, said linkage including a member which is adjustable to reduce, in response to increase in airspeed, the movement imparted by the linkage to the input member per unit of movement of the control member, a hydraulic jack including a piston member and a housing member, one of said members being movable in response to variations in hydraulic pressure in the housing member and being connected to said adjustable member, a spring opposing movement of said movable member, a control valve subject to the hydraulic pressure in the housing member and normally closing an outlet from said housing member, said control valve being movable in opposite directions from a normal position to supply liquid under pressure to said housing member and to allow liquid to flow to exhaust from said housing member, a pressure-sensitive device exposed to the diflerence between total pressure and static pressure and arranged to exert on
Description
May 3, 1960 R. WESTBURY ETAL 2,935,276
AIRCRAFT CONTROL SYSTEM 3 Sheets-Sheet 1 Filed May 25, 1955 May 3, 1950 WESTBURY ETAL 2,935,276
AIRCRAFT CONTROL SYSTEM 3 Sheets-Sheet 2 May 3, 1966 R. WESTBURY ET L 2,935,276
AIRCRAFT CONTROL SYSTEM Filed May 25, 1955 3 Sheets-Sheet 3 United States Patent AIRCRAFT CONTROL SYSTEM Roy Westbury, Bridgnorth, Salop, England, and Charles Philip Smith, Ramsay, Isle of Man, assignors to H. M. Hobson Limited, London, England, a British company Application May 25, 1955, Serial No. 510,931
Claims priority, application Great Britain June 3, 1954 4 Claims. (Cl. 244-83) Due to the wide speed range of modern high speed aircraft, the aerodynamic control surfaces become extremely powerful at the high speed end of the range. In a typical case, the elevator may, for example, be safely given an angular displacement of 20 at take-off and landing speeds while at the maximum subsonic indicated speed an angular displacement of as little as 2 or 3 might be sufficient to break the aircraft.
Clearly therefore the displacements imparted by the pilot to his stick in high speed flight are extremely small and difficulty is sometimes experienced due to the oversensitive control system.
With a view to obviating this diificulty, the invention provides, in or for an aircraft, a flying control system embodying a variable gearing between the pilots stick and a control surface to be operated thereby and means for automatically changing the gearing in response to increase in air speed so that the travel of the stick required to produce unit displacement of the control surface in creases as the air speed increases.
Thus the stick may be connected to the input member of a servo mechanism for actuating the control surface by means of a linkage embodying an adjustable fulcrum, a device responsive to changes in air speed being provided for automatically adjusting said fulcrum so that the travel of the stick required to produce unit displacement of the control surface increases as the air speed increases.
The device responsive to changes in air speed may be arranged to adjust said fulcrum through the agency of a hydraulic jack as described in United States patent applications Nos. 407,536 filed February 1, 1954, now U.S. Patent No. 2,783,006, granted February 26, 1927, and 458,334 filed September 27, 1954, now US. Patent No. 2,788,185, granted April 9, "1957. ternatively, as later described, an electric actuator may be used for the purpose.
The device responsive to changes in air speed may be employed solely to change the gear ratio between the stick and the control surface and introduce no variable stiffness in the stick, which is provided with a conventional spring centering device. The gear change provided may be such that the stick force per unit of acceleration imparted to the aircraft in a manoeuvre is constant. The pilot will then require to displace his stick to the same extent, to obtain a given acceleration of the aircraft, over the entire speed range. However, as later explained, it is in some cases undesirable to provide means whereby the stick force per g varies at some limiting value or values of air speed or Mach number. Also, the device responsive to changes in air speed may be arranged not only to change the gear ratio but may also act as a feel simulator to impose a resistance to movement of the stick whi h in creases with air speed.
Certain embodiments of the invention will now be described in more detail, by way of example, with reference to the accompanying drawings, in which:
Fig. 1 is a diagrammatic view of a complete flying control system utilising a hydraulic jack to produce a gear change only,
Fig. 2 is a detail view showing a modification of the system of Fig. 1,
Fig. 3 is a diagrammatic view of part of a system, similar to that of Fig. 1 but with the hydraulic jack arranged to act also as a feel simulator, and
Fig. 4 is a vertical section through an alternative form of air speed responsive device for use in conjunction with the systems shown in Figs. 1 and 3.
Like reference numerals indicate like parts throughout the figures.
In the system shown in Fig. 1, the stick 20, which is provided with centering springs 21, is connected by a mechanical linkage to a link 25 connected to the input member of a hydraulic jack 22 for actuating a control surface 23. The jack 22 is of conventional type and includes a control valve movable in opposite directions from a neutral position by a rod 24 to establish alternative pressure and exhaust connections to opposite ends f the jack cylinder and thereby to cause corresponding movement, in one direction or the other, of the jack piston, the rod 26 of which is connected to the control surface and also, by means of the usual follow-up link 27, to the rod 24 and to the link 25. The mechanical linkage comprises a link 28, carrying a pin 29 engaging a slot 36 in a lever 60, pivoted at one end at a fixed point 31 and pivoted at the other end 32 to the link 25. The gear change is effected by changing the position of the pin 29 in the slot 30, as will now be described.
The position of the pin 29 in the slot 36 is controlled by a hydraulic jack 33, the piston 34 of which is anchored at a fixed point 35 and the cylinder 36 of which is connected to the aircraft structure by a stifi spring 37 and is also pivoted to a lever 38. The lever 38 is mounted on a fixed pivot 39 and is connected by a link 40 to the link 28.
The hydraulic pressure in the cylinder 36 is caused to increase as the airspeed increases by an air speed responsive unit 41 of the kind described in United States appli-, cation No. 407,536/54. This includes a diaphragm 42, subject from a Pitot head 43, through pipes 44, 45, to total or ram pressure P, at its upper surface and to static pressure P at its undersurface. The unit 41 includes a control valve 46 which serves to determine the hydraulic pressure in a signal line 47 communicating with the cylinder 36. A push rod 48, carrying a valve 49 at its lower end, is interposed between the diaphragm 42 and the control valve 46, which is subject at its undersurface to the signal pressure, which is applied thereto through a duct 54).
Normally, the control valve 46 occupies the neutral position shown, the signal pressure on its undersurface assisted by the pressure of a spring 51, balancing the pressure differential across the diaphragm 42. If the air speed increases, the control valve 46 will be depressed, so connecting the signal line 47 to a pressure inlet 52. The signal pressure accordingly increases to a value at which it is sufiicient to return the control valve to its neutral position. On decrease in the air speed, the control valve 46 rises, connecting the signal line 47 to an exhaust outlet 53, thus allowing the signal pressure to fall to a value at which the diaphragm 42 is able to return the control valve 45 to its neutral position. The signal pressure is applied through a duct 54 to the undersurface of the valve 49, which opens, as described in United States application No. 407,536/54, to permit of reduction of the signal pressure it, as the result of seizure of the control valve 46, the signal pressure should become excessive.
The pressure in the cylinder 36 thus increases with increase in air speed and so gradually lifts the cylinder against the action of the spring 37, rocking the lever 38 clockwise and causing the pin 29 to move down in the 5101130. The, travelof the. stickrequiredto. produce. unitv displacement of the controLsurface thus increases as the air speed increases.
In certain circumstances thesystem so. far'described may render the aircraft statically unstable. Thus, in the case of operation of the-elevator, the following sequence of operations may occur:
(1) The pilot eases the stick back.
(2) The aircraft noses up.
(3) As soon as the aircraft is climbing, the speed drops.
(4) The unit 41 senses the reduction in speed and re duces the hydraulic pressure in the cylinder 36.
, (5) The link 40 moves up to lift the. pin29: in the siot 3!). the lever 60 is. at this timein a position inclined to the vertical, the movement of the pin 29 in the slot 39 will impart, without. any further stick movement by the pilot, an additional displacement to the, elevator,
(6,) The ircraft noses. up-still further, the, speed drops still more and thecycleof events continues.
This can. be prevented by inclining the slot 39 at an angle to the lengthwise direction of the lever 6% as shown in Fig. 2. Then, when the lever 60 is in the position which it assumes when the stick. is eased back, movement of the pin 29 in the slot 30 in response to reduction of the hydraulic pressure in the cylinder 36 will have no efiect on the position of the control surface. Accordingly within the limits of the trim range, vertical displacement of the pin 29 will not produce a positive increase in the angular displacement of the elevator in relation to the position of the stick. In the stick forward position, the tendency of the hydraulic pressure in the cylinder 36 is to impart less movement to the elevator in response to increase in speed of the aircraft, but thisdoes not matter as this is a stable and not an unstable condition.
The system shown in Fig. 3 differs from that of Fig. 1 in that the stick is pivoted to the rod 550i the piston 34, the centering springs being omitted. The hydraulic jack 33 thus serves not only to provide the gear change, by shifting the pin 29 in the slot 30, but also as a feel simulator, providing, as in the case of United States application No. 407,536, a resistance to movement of the stick which increases with increase in air speed.
In the arrangements so far described, the adjustable fulcrum in the linkage between the stick and the input 7 member of the jack for actuating the control surface will continue to be adjusted progressively as the air speed increases. It will be understood, however, that the relationship between air pressure and the'signal pressure communicated to cylinder 36 of the jack 33 in Figs. 1 and 3 may be made non-linear by utilizing any of the expedients described in United States applications Nos.
407,536/54 and 458,334/54. Thus, by the, provision of a stop to arrest'continued movement of the diaphragm 42 we may arrange that there will be no further gear change after the 'air speed has. increased beyond a given limit. Again, we can'arrange for a second pressure sensitive device to become operative, at a given air speed'or Mach number, to exert a force on the control valve 46 in opponection to the diaphragm 42, 67' another total pressure connection to, a diaphragm 68 described later, 69 the static pressure connection tothe unit and 70 the outlet to the signal line.
A diaphragm 71 is also exposed to the pressure difierenease-ar f diaphragm 71 is smaller than the diaphragm 42, the signal pressure will continue to. increase with air speed but at a slower rate. If the diaphragm 71 is. largerthan-the diaphragm 42, the signal pressure will decrease as the air speed increases beyondthe. given value.
The diaphragm 68 carries, at the side thereof exposed to total pressure'through the connection 67, an evacuated.
What we claim as our invention and desire to secure by Letters Patent is:
l. A power operated flying control system for aircraft, comprising a control surface, a. pilots control member, a servo mechanism having an input member and an output member, said output member being connected to and serving to actuate the control surface, a linkage connecting the controlmember to the input memher, said linkage including a member which is adjustable to reduce, in response to increase in airspeed, the movement imparted by the linkage to the input member per unit of movement of the control member, a hydraulic jack including a piston member and a housing member, said housing member being movable in response to variations in hydraulic pressure in the housing and being connected to said adjustable linkage member and said piston member being connected to said control member and movable therewith against the resistance offered by the hydraulic pressure in the housing member, a spring opposing movement of said housing member, means re sponsive to changes in airspeed and means controlled byv said responsive device to establish in said housing member a variable hydraulic pressure which increases progressively asthe airspeed increases up to a given value at least of airspeed, said housing member moving 7 to adjust the adjustable linkage member in response to tial P, -P',, which acts in the direction to move the dia-' phragm 71 away from the diaphragm 42, and is balanced against this pressure diiferential by a spring 72. The
diaphragm -71 carriesa stud;.73 moving with clearance in a claw 74fixed" to the diaphragm 42. When the'afore liquidto-iiow'to exhaust from saidhousing'inember, 21
changes in said hydraulic pressure. a
2. A power operated flying control system forair craft, comprising a control surface, a pilots control member, a servo mechanism having an input member and an output member, said output member being connected to andserving to actuate the control surface, a linkage connecting the control member to the input member, said linkage including a member which is adjustable to reduce, in response to increase'in airspeed, the movementvimparted by the linkage to the input member per unit of movement of the control member, azhydraulic jack including a piston member and a housing member, one of said members being movable in response to variations in hydraulic. pressure in the housingmember and being'connected to said adjustable member, a spring opposing movement of said movable member, a control valve subject to the hydraulic pressure in the housing member and normally closing an outlet from saidhousing member, said control valve being movable in opposite directions from a normal position to supply liquid under pressure to said housing member and to allow diaphragm exposed to the difference between total pressure and static pressure and arranged to exert on the control valve a force opposing the hydraulic pressure in the housing member, said force increasing with increase in airspeed, said diaphragm controlling said control valve to maintain in the housing member a hydraulic pressure which increases with air speed and said movable member moving in response to change in said hydraulic pressure to adjust said adjustable linkage member, a second diaphragm extending parallel to said diaphragm and also exposed to the difierence between total pressure and static pressure and a lost motion connection between the two diaphragms, said second diaphragm being mounted to move away from the other diaphragm in response to increase in airspeed and being effective, when a given airspeed is exceeded, to apply force to the other diaphragm through said lost motion connection.
3. A power operated flying control system for aircraft, comprising a control surface, a pilots control member, a servo mechanism having an input member and an output member, said output member being connected to and serving to actuate the control surface, a linkage connecting the control member to the input member, said linkage including a member which is adjustable to reduce, in response to increase in airspeed, the movement imparted by the linkage to the input member per unit of movement of the control member, a hydraulic jack including a piston member and a housing member, one of said members being movable in response to variations in hydraulic pressure in the housing member and being connected to said adjustable member, a spring opposing movement of said movable member, a control valve subject to the hydraulic pressure in the housing member and normally closing an outlet from said housing member, said control valve being movable in opposite directions from a normal position to supply liquid under pressure to said housing member and to allow liquid to flow to exhaust from said housing member, a pressure-sensitive device exposed to the difierence between total pressure and static pressure and arranged to exert on the control valve a force opposing the hydraulic pressure in the housing member, said force increasing with increase in airspeed, said pressure-sensitive device controlling said control valve to maintain in the housing member a hydraulic pressure which increases with airspeed and said movable member moving in response to change in said hydraulic pressure to adjust said adjustable linkage member, and a normally inoperative device responsive to Mach number arranged, when a predetermined Mach number is attained, to act on the control valve in opposition to the pressure-sensitive device and thereafter to modify the control exerted by the pressure-sensitive device on the hydraulic pressure in the housing member.
4. A power operated flying control system for aircraft, comprising a control surface, a pilots control member, a servo mechanism having an input member and an output member, said output member being connected to and serving to actuate the control surface, a linkage connecting the control member to the input memher, said linkage including a member which is adjustable to reduce, in response to increase in airspeed, the movement imparted by the linkage to the input member per unit of movement of the control member, a hydraulic jack including a piston member and a housing member, one of said members being movable in response to variations in hydraulic pressure in the housing member and being connected to said adjustable member, a spring opposing movement of said movable member, a control valve subject to the hydraulic pressure in the housing member and normally closing an outlet from said housing member, said control valve being movable in opposite directions from a normal position to supply liquid under pressure to said housing member and to allow liquid to flow to exhaust from said housing member, a pressure-sensitive device exposed to the diflerence between total pressure and static pressure and arranged to exert on the control valve a force opposing the hydraulic pressure in the housing member, said force increasing with increase in airspeed, said pressure-sensitive device controlling said control valve to maintain in the housing member a hydraulic pressure which increases with airspeed and said movable member moving in response to change in said hydraulic pressure to adjust said adjustable linkage member, a normally inoperative device responsive to Mach number, and an intermediately pivoted lever bearing at one end on said responsive device and having its other end normally spaced from the pressure-sensitive device, said lever moving, when a predetermined Mach number is attained, into contact with the pressure-sensitive device to permit the responsive device to apply to the pressure-sensitive device a force opposing the air pressure acting thereon.
References Cited in the file of this patent UNITED STATES PATENTS 1,896,999 Bertram Feb. 7, 1933 2,205,610 Van Nes June 25, 1940 2,342,184 Fawcett Feb. 22, 1944 2,395,671 Kleinhans et a1. Feb. 26, 1946 2,548,481 Knowler et al Apr. 10, 1951 2,652,994 Feeney Sept. 22, 1953 FOREIGN PATENTS 339,399 Italy Apr. 18, 1936 1,098,262 France Mar. 2, 1955
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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GB2935276X | 1954-06-03 |
Publications (1)
Publication Number | Publication Date |
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US2935276A true US2935276A (en) | 1960-05-03 |
Family
ID=10918120
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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US510931A Expired - Lifetime US2935276A (en) | 1954-06-03 | 1955-05-25 | Aircraft control system |
Country Status (1)
Country | Link |
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US (1) | US2935276A (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3309937A (en) * | 1965-02-02 | 1967-03-21 | Piasecki Aircraft Corp | Coordinating control linkage |
US3374850A (en) * | 1966-08-02 | 1968-03-26 | Int Harvester Co | Resiliently biased steering system |
US4599070A (en) * | 1981-07-29 | 1986-07-08 | Control Interface Company Limited | Aircraft simulator and simulated control system therefor |
Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
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US1896999A (en) * | 1932-02-12 | 1933-02-07 | Chas M Stieff Inc | Aircraft control means |
US2205610A (en) * | 1937-06-07 | 1940-06-25 | Arado Flugzeugwerke Gmbh | Safety control for aircraft |
US2342184A (en) * | 1940-05-20 | 1944-02-22 | Charles C Fawcett | Automatic control for aircraft equipment |
US2395671A (en) * | 1940-09-26 | 1946-02-26 | Douglas Aircraft Co Inc | Control means for airfoils |
US2548481A (en) * | 1946-10-16 | 1951-04-10 | Saunders Roe Ltd | Flying control for aircraft |
US2652994A (en) * | 1948-08-30 | 1953-09-22 | Northrop Aircraft Inc | Motion ratio changer |
FR1098262A (en) * | 1953-02-02 | 1955-07-21 | Hobson Ltd H M | Aircraft control sensitizer |
-
1955
- 1955-05-25 US US510931A patent/US2935276A/en not_active Expired - Lifetime
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US1896999A (en) * | 1932-02-12 | 1933-02-07 | Chas M Stieff Inc | Aircraft control means |
US2205610A (en) * | 1937-06-07 | 1940-06-25 | Arado Flugzeugwerke Gmbh | Safety control for aircraft |
US2342184A (en) * | 1940-05-20 | 1944-02-22 | Charles C Fawcett | Automatic control for aircraft equipment |
US2395671A (en) * | 1940-09-26 | 1946-02-26 | Douglas Aircraft Co Inc | Control means for airfoils |
US2548481A (en) * | 1946-10-16 | 1951-04-10 | Saunders Roe Ltd | Flying control for aircraft |
US2652994A (en) * | 1948-08-30 | 1953-09-22 | Northrop Aircraft Inc | Motion ratio changer |
FR1098262A (en) * | 1953-02-02 | 1955-07-21 | Hobson Ltd H M | Aircraft control sensitizer |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3309937A (en) * | 1965-02-02 | 1967-03-21 | Piasecki Aircraft Corp | Coordinating control linkage |
US3374850A (en) * | 1966-08-02 | 1968-03-26 | Int Harvester Co | Resiliently biased steering system |
US4599070A (en) * | 1981-07-29 | 1986-07-08 | Control Interface Company Limited | Aircraft simulator and simulated control system therefor |
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